G. Rotella, O.W. Dillon, D. Umbrello, L. Settineri, I.S. Jawahir, Finite element modeling of microstructural changes in turning of AA7075-T651 Alloy, Journal of Manufacturing Processes,
Volume 15, Issue 1, 2013, pp. 87-95, ISSN 1526-6125.
 Furumoto, T., Abe, S., Yamaguchi, M. et al. Improving surface quality using laser scanning and machining strategy combining powder bed fusion and machining processes. Int J Adv Manuf Technol 117, 3405–3413 (2021).
 Calamaz, M., Coupard, D., Nouari, M. et al. Numerical analysis of chip formation and shear localisation processes in machining the Ti-6Al-4V titanium alloy. Int J Adv Manuf Technol 52, 887–895 (2011). https://doi.org/10.1007/s00170-010-2789-x
 Ravindranadh Bobbili, Vemuri Madhu, A modified Johnson-Cook model for FeCoNiCr high entropy alloy over a wide range of strain rates, Materials Letters, 218, 2018, pp. 103-105, https://doi.org/10.1016/j.matlet.2018.01.163.
 M. Alitavoli, A. Darvizeh, M. Moghaddam, P. Parghou, R. Rajabiehfard, Numerical modeling based on coupled Eulerian-Lagrangian approach and experimental investigation of water jet spot welding process, Thin-Walled Structures, Volume 127, 2018, pp. 617-628, ISSN 0263-8231, https://doi.org/10.1016/j.tws.2018.02.005.
 S. Imbrogno, G. Rotella, S. Rinaldi, Surface and subsurface modifications of AA7075-T6 induced by dry and cryogenic high speed machining, The International Journal of Advanced Manufacturing Technology volume 107: 905–918 (2020)
 K. Ma, H. Wen, T. Hu, T. D. Topping, D. Isheim, D. N. Seidman, E. J. Lavernia, J. M. Schoenung, (2014), Mechanical behavior and strengthening mechanisms in ultrafine grain precipitation-strengthened aluminum alloy, Acta Materialia, 61: 141-155.
 M. Dixit, R. S. Mishra, K. K. Sankaran, (2008), Structure–property correlations in Al 7050 and Al 7055 high-strength aluminum alloys, Materials Science and Engineering A, 478: 163–172.
 Y. H. Zhao, X. Z. Liao, Z. Jin, R. Z. Valiev, Y. T. Zhu, (2004), Microstructures and mechanical properties of ultrafine grained 7075 Al alloy processed by ECAP and their evolutions during annealing, Acta Materialia, 52: 4589-4599.
 U.F. Kocks, A statistical theory of flow stress and work-hardening, Philosophical Magazine, 13 (1966), pp. 541-566
 S. N. Melkote, R. Liu, P. F. Zelaia, T. Marusich, (2015), A physically based constitutive model for simulation of segmented chip formation in orthogonal cutting of commercially pure titanium, Cirp Annals, 64: 65-68.
 I. Sabirov, M. Y. Murashkin, R. Z. Valiev, (2013), Nanostructured aluminium alloys produced by severe plastic deformation: New horizons in development, Materials Science and Engineering A, 560: 1-24.
 T.D. Topping, B. Ahn, Y. Li, S.R. Nutt, E.J. Lavernia, (2012), Influence of Process Parameters on the Mechanical Behavior of an Ultrafine-Grained Al Alloy, Metallurgical and Materials Transactions A, 43: 505-519.
 J. Gubicza, I. Schiller, N.Q. Chinh, J. Illy, Z. Horita, T.G. Langdon, (2007), The effect of severe plastic deformation on precipitation in supersaturated Al–Zn–Mg alloys, Materials Science and Engineering A: 461: 77–85.
 H. Frost, M. Ashby, (1977b), Deformation-mechanism maps for pure iron, two austenitic stainless steels and a low-alloy ferritic steel. In: Jaffee, R.I., Wilcox, B.A. (Eds.), Fundamental Aspects of Structural Alloy Design. Plenum Press, pp. 26–65.
 H. Conrad, (1970), The athermal component of the flow stress in crystalline solids, Material Science and Engineering A, 6: 265–273.
 E. Arzt, Size effects in materials due to microstructural and dimensional constraints: a comparative review, Acta Materialia, 46 (16): 5611-5626.
 A. Seeger, (1956) The mechanism of Glide and Work Hardening in FCC and HCP Metals. In: Fisher, J., Johnston, W.G., Thomson, R., Vreeland, T.J. (Eds.), Dislocations and Mechanical Properties of Crystals, pp. 243–329.
 Y. Bergström, (1983), The plastic deformation of metals - A dislocation model and its applicability. Reviews on powder metallurgy and physical ceramics 2/3: 79–265.
 D. Holt, (1970), Dislocation cell formation in metals, Journal of Applied Physics, 41: 3197-3201.
 T. L. Johnson, C. E. Feltner, Grain size effects in the strain hardening of polycrystals, Metallurgical and Materials Transactions B volume 1, 1161 (1970)
 A. V. Lubarda, On Atomic Disregistry, Misfit Energy, and the Peierls Stress of a Crystalline Dislocation, THE MONTENEGRIN ACADEMY OF SCIENCES AND ARTS PROCEEDINGS OF THE SECTION OF NATURAL SCIENCES, 17, 2007
 S. Takeuchi (2001), The mechanism of the inverse Hall-Petch relation of nanocrystals, Scripta Materialia Volume 44 (8–9): 1483-1487.
 R. O. Scattergood, C. C. Kock, (1992), A modified model for Hall-Petch behavior in nanocrystalline materials, Scripta Metallurgica et Materialia, 27: 1195-1200.
 G. J. Thomas, R.W. Siegel, J.A. Eastman, (1990), Grain boundaries in nanophase palladium: high resolution electron microscopy and image simulation, Scripta Metallurgica et Materialia, 24: 201-206.
 H. Hallberg, M. Wallin, M. Ristinmaa, (2010), Modelling of continuous dynamic recrystallization in commercial-purity aluminum, Materials Science and Engineering A, 527: 1126–1134.
 G. Z. Quan, Y. P. Mao, G. S. Li, W. Q. Lv, Y. Wang, J. Zhou, (2012), A characterization for the dynamic recrystallization kinetics of as-extruded 7075 aluminum alloy based on true stress–strain curves, Computational Material Science, 55: 65-72.
 C. Shi, W. Mao, X. G. Chen, (2013), Evolution of activation energy during hot deformation of AA7150 aluminum alloy, Materials Science and Engineering A 571: 83-91.
 D. Caillard, J. L. Martin, (2003), Thermally Activated Mechanisms in Crystal Plasticity, Pergamon, Oxford.
 H. Frost, M. Ashby, (1982), Deformation-mechanism maps - the plasticity and creep of metals and ceramics, Pergamon Press, Oxford.
 M. Nicolas, A. Deschamps, (2003), Precipitate Microstructures and Resulting Properties of Al-Zn-Mg Metal Inert Gas–Weld Heat-Affected Zones, Metallurgical and Materials Transactions A, 35: 1437-1448
 O. Ryen, O. Nijs, E. Sjolander, B. Holmedal, H.E. Ekstrom, E. Nes, (2006), Strengthening mechanisms in solid solution aluminum alloys, Metallurgical and Materials Transactions A, 37: 1999-2006.
 V. P. Astakhov, S. Joksch, (2012), Metalworking fluids (MWFs) for cutting and grinding – fundamentals and recent advances: 147–151; Cambridge, UK, Woodhead Publishing Limited, 1.
 F. Pušavec, T. Lu, C. Courbon, J. Rech, U. Aljancic, J. Kopac, I. S. Jawahir, (2016), Analysis of the influence of nitrogen phase and surface heat transfer coefficient on cryogenic machining performance, Journal of Materials Processing Technology, 233: 19-28.
 A. Bordin, S. Imbrogno, G. Rotella, S. Bruschi, A. Ghiotti, D. Umbrello, Finite Element Simulation of Semi-finishing Turning of Electron Beam Melted Ti6Al4V Under Dry and Cryogenic Cooling Procedia CIRP, 31 (2015), pp. 551-556.
 T. Özel, (2006), The influence of friction models on finite element simulations of machining, International Journal of Machine Tools and Manufacture, 46: 518–530.
 P. J. Arrazola, T. Ӧzel, (2010), Investigations on the effects of friction modeling in finite element simulation of machining, International Journal of Mechanical Sciences, 52: 31-42.
 F. Cabanettes, J. Rolland, F. Dumont, J. Rech, Z. Dimkovski, (2016), Influence of Minimum Quantity Lubrication on friction characterizing tool-aluminum alloy contact, Journal of Tribology, 138: 1-10.
 S. Imbrogno, G. Rotella, S. Rinaldi (2020), Surface and subsurface modifications of AA7075-T6 induced by dry and cryogenic high speed machining, The International Journal of Advanced Manufacturing Technology, 107: 905–918.